Numerical experiments on forced-damped NLS waves identify a forcing-independent quadratic link between kurtosis and bandwidth for single-spectrum rogue wave prediction.
Wave amplification in the framework of forced nonlinear Schrodinger equation: the rogue wave context
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abstract
Irregular waves which experience the time-limited external forcing within the framework of the nonlinear Schrodinger (NLS) equation are studied numerically. It is shown that the adiabatically slow pumping (the time scale of forcing is much longer than the nonlinear time scale) results in selective enhancement of the solitary part of the wave ensemble. The slow forcing provides eventually wider wavenumber spectra, larger values of kurtosis and higher probability of large waves. In the opposite case of rapid forcing the nonlinear waves readjust passing through the stage of fast surges of statistical characteristics. Single forced envelope solitons are considered with the purpose to better identify the role of coherent wave groups. An approximate description on the basis of solutions of the integrable NLS equation is provided. Applicability of the Benjamin - Feir Index to forecasting of conditions favourable for rogue waves is discussed.
fields
physics.flu-dyn 1years
2019 1verdicts
UNVERDICTED 1representative citing papers
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Single-spectrum prediction of kurtosis of water waves in a non-conservative model
Numerical experiments on forced-damped NLS waves identify a forcing-independent quadratic link between kurtosis and bandwidth for single-spectrum rogue wave prediction.